Research and evaluate the advantages of flow interpolation method in identify areas of concentrated water
Автор: Nguyen Thi Thu Nga, Nguyen Nhu Hung, Trinh Le Hung
Журнал: Вестник аграрной науки @vestnikogau
Статья в выпуске: 6 (51), 2014 года.
Бесплатный доступ
Interpolation method has been used effectively in the determination of the direction of flow and the concentration of water. The direction of the flow surface is one of the most important factors in the study of concentration of water. Waters concentrated is cumulative line area terrain understand if the rivers and streams of water supply network focused on it. The determination of the concentration of water directly affects research results in study of floods, landslides, erosion and indirectly affects to the construction of hydroelectric dam reservoirs, canals. Choosing an interpolation methods accurate flow is very important. So, in this article, the author focuses on the advantages of interpolation methods D∞ flow and its effects to the establishment of centralized water than other methods.
Digital elevation model, interpolation method, direction of flow, concentration of water, geographical information system
Короткий адрес: https://sciup.org/147124554
IDR: 147124554
Список литературы Research and evaluate the advantages of flow interpolation method in identify areas of concentrated water
- Tesfa, T. K., D. G. Tarboton, D. W. Watson, K. A. T. Schreuders, M. E. Baker and R. M. Wallace, (2011), «Extraction of hydrological proximity measures from DEMs using parallel processing,» Environmental Modeling & Software, 26(12): 1696-1709.
- Tarboton, D. G., (1989), «The analysis of river basins and channel networks using digital terrain data,» Sc.D. Thesis, M.I.T., Cambridge, MA, (Also available as Tarboton D. G., R. L. Bras and I. Rodriguez-Iturbe, (Same title), Technical report no 326, Ralph M. Parsons Laboratory for Water resources.
- Terrain Analysis: Principles and Applications, John Wiley and Sons, Wilson, J. P. and J. C. Gallant, (2000), New York, 479 p.
- Wilson, J. P. and J. C. Gallant, (2000), Terrain Analysis: Principles and Applications Wiley and Sons, New York, 479 p.
- Tarboton, D. G., (2003), «Terrain Analysis Using Digital Elevation Models in Hydrology,» 23rd ESRI International Users Conference, San Diego, California, July 7-11.
- Tarboton, D. G., (2003), «Terrain Analysis Using Digital Elevation Models in Hydrology,» 23rd ESRI International Users Conference, San Diego, California, July 7-11.
- Tarboton, D. G., R. L. Bras and I. Rodriguez-Iturbe, (1991), «On the Extraction of Channel Networks from Digital Elevation Data,» Hydrologic Processes, 5(1): 81-100
- Tarboton, D. G., K. A. T. Schreuders, D. W. Watson and M. E. Baker, (2009), «Generalized terrain-based flow analysis of digital elevation models,» 18th World IMACS Congress and MODSIM09 International Congress on Modelling and Simulation, ed. R. S. Anderssen, R. D. Braddock and L. T. H. Newham, Modelling and Simulation Society of Australia and New Zealand and International Association for Mathematics and Computers in Simulation, July 2009, p.2000-2006.
- Wallis, C., D. Watson, D. G. Tarboton and R. Wallace, (2009), «Parallel Flow-Direction and Contributing Area Calculation for Hydrology Analysis in Digital Elevation Models,» PDPTA'09, The 2009 International Conference on Parallel and Distributed Processing Techniques and Applications, Las Vegas, Nevada, USA, July 13-16.
- Wallace, R. M., D. G. Tarboton, D. W. Watson, K. A. T. Schreuders and T. K. Tesfa, (2010), «Parallel Algorithms for Processing Hydrologic Properties from Digital Terrain,» GIScience 2010, Sixth international conference on Geographic Information Science, Zurich, Switzerland, September 14-17.
